This disclosure concerns methods for processing and grading food articles including x-raying the food articles a first time and taking a 3D image of the food articles.

A handheld injector is provided for injecting liquid, such as flavoring or basting material, into meat or poultry. The injector includes a pistol-shaped housing which encloses a battery-powered motor for constant-rate delivery of liquid from a peristaltic pump. The injector also includes a fluid conduit within the housing through which liquid is pumped from a reservoir of liquid to a needle for injection into the meat.

An apparatus for grading/batching food parts includes a scale unit with a first predetermined precision, a plurality of batch bins to receive food parts, a weighing station to weigh food parts, which have not yet been transferred into the bins, with a second predetermined precision greater than the first predetermined precision and to associate the determined weights with the corresponding food part, a plurality of controllable second transfer units to selectively transfer particular ones of said food parts, which have been weighed into a selected one of the bins, and a control unit connected with the scale unit, weighing station, and first and second transfer units. The control unit controls the first and second transfer unit to assemble in the bins food parts so the total weight in each bin corresponds to a predetermined target weight. A method for grading/batching, and an apparatus/method for transferring food parts is also provided.

A cartilage cutting device for a bone-in meat according to an embodiment includes a cutting blade disposed on a conveying path for a bone-in meat and an elastic support portion for elastically supporting the cutting blade so that the cutting blade can recede by a reaction force applied to the cutting blade when cutting the bone-in meat. The elastic support portion is configured such that an elastic supporting force of the elastic support portion is switchable between a first elastic supporting force and a second elastic supporting force. The first elastic supporting force is capable of cutting a cartilage adhering to a bone part of the bone-in meat. The second elastic supporting force is smaller than the first elastic supporting force and is incapable of cutting the cartilage.

The present disclosure provides a mechanical system for providing a food product on a sheet of paper. The disclosed mechanical system includes an adjustable conveyor belt system that is configured to enable a puck of food product to land up-right. The angle (e.g., slope) of the adjustable conveyor belt system can be adjusted to account for variations in the size and shape of the puck. The disclosed mechanical system also includes a flattener that is configured to provide memory to the pressed pucks.

The present disclosure provides a preservation method for room temperature logistics of fresh meat, e.g., pork, including the following steps: cutting a slaughtered pig into pieces while the pork is hot, and cooling to 0° C. to 4° C.; cooling again to −4° C. to −2° C. so that the meat pieces reach a chilled/slightly-frozen state; sub-packaging the chilled/slightly-frozen meat pieces; putting sub-packaging boxes with fresh meat pieces into an insulation foam box together with ice bags for packaging; and using a room temperature logistics vehicle for transportation and distribution, where, when in an ambient temperature is at least 24° C. (e.g., summer), transportation and distribution time is ≤36 h; and when the ambient temperature is less than 24° C. (e.g., spring, autumn, and winter), the transportation and distribution time is ≤72 h.

A processing system for bone-in limb meats according to an embodiment includes: a right-limb incision-forming portion for forming incision on a right bone-in limb meat; a left-limb incision-forming portion for forming incision on a left bone-in limb meat; a processing line including a plurality of processing stations to separate a bone part and a meat part of each bone-in limb meat on which incision is formed at the right-limb incision-forming portion or the left-limb incision-forming portion; and a loading portion arranged at an uppermost stream part of the processing line to receive the right bone-in limb meat with incision formed at the right-limb incision-forming portion and the left bone-in limb meat with incision formed at the left-limb incision-forming portion.

A processing system for bone-in limb meats according to an embodiment includes: a right-limb incision-forming portion for forming incision on a right bone-in limb meat; a left-limb incision-forming portion for forming incision on a left bone-in limb meat; a processing line including a plurality of processing stations to separate a bone part and a meat part of each bone-in limb meat on which incision is formed at the right-limb incision-forming portion or the left-limb incision-forming portion; and a loading portion arranged at an uppermost stream part of the processing line to receive the right bone-in limb meat with incision formed at the right-limb incision-forming portion and the left bone-in limb meat with incision formed at the left-limb incision-forming portion.

A multi-angle wash system for cleaning carcass, wherein the wash system comprises a multi-angle fluid distribution unit; a rotating unit; a spray unit fluidly and operably coupled to the multi-angle fluid distribution unit; and a guiding unit operably coupled to the spray unit or the multi-angle fluid distribution unit. The multi-angle fluid distribution unit comprises a connecting element that is configured to operably couple with the spray unit such that the spray unit oscillates in correspondence to the rotation of the rotating unit. The spray unit comprises a guiding element and nozzle sprays. The guiding unit comprises a co-guiding element that has a reciprocate structure to the guiding element of the spray unit such that the guiding unit facilitates the oscillation of the spray unit in correspondence to the rotation of the rotating unit.

A system 10 for analyzing and trimming pork bellies and other three-dimensional food and non-food products which are to be subsequently portioned or sliced so as to achieve an optimum harvest of slices from the food product bearing in mind achieving a maximum yield together with a desired quality level of the portions/slices. The system 10 includes a conveyor 12 for carrying the workpieces (WP) to be trimmed prior to subsequent slicing of the workpiece past a scanning system 14 for scanning the workpiece WP to ascertain the physical characteristics of the workpiece, including, for example, its three-dimensional shape as well as its position on the conveyor. A cutting station 16 trims the workpiece WP into a desired two-dimensional shape which represents an optimum shape for the workpiece that seeks to maximize the harvest of slices from the workpiece while maintaining a desired quality level for the slices. A slicing station uses high speed cutters or slicers for portioning/slicing the workpiece into portions/slices which have been simulated by a processing system 18 employing a processor or computer 20.